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===Therapeutic Implications===
 
===Therapeutic Implications===
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Due to their reliance on oxidative phosphorylation ''IDH1''-mutated cancer cells are vulnerable to inhibitors of this metabolic process. The biguanides metformin and phenformin inhibit NADH dehydrogenase (complex I of the electron transport chain (ETC)), and ''IDH1'' mutations confer sensitivity to these agents[65]; metformin is currently undergoing clinical trial for use in patients with ''IDH1/2''-mutant solid tumours [66].  
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Due to their reliance on oxidative phosphorylation ''IDH1''-mutated cancer cells are vulnerable to inhibitors of this metabolic process. The biguanides metformin and phenformin inhibit NADH dehydrogenase (complex I of the electron transport chain (ETC)), and ''IDH1'' mutations confer sensitivity to these agents [65]; metformin is currently undergoing clinical trial for use in patients with ''IDH1/2''-mutant solid tumors [66].  
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''IDH1''-mutated cells also have a dependence on the glutaminolysis pathway. Although ''IDH1''-mutated cells need αKG to produce 2HG, they also restrict αKG production[5]. Producing αKG from glutamine allows for an alternative source of αKG in ''IDH''-mutated cells, but makes the cells vulnerable to inhibition of glutaminolysis with agents such as aminooxyacetic acid, BPTES, zaprinast, and chloroquinine in various cell types [67–70].  
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''IDH1''-mutated cells also have a dependence on the glutaminolysis pathway. Although ''IDH1''-mutated cells need αKG to produce 2HG, they also restrict αKG production [5]. Producing αKG from glutamine allows for an alternative source of αKG in ''IDH''-mutated cells, but makes the cells vulnerable to inhibition of glutaminolysis with agents such as aminooxyacetic acid, BPTES, zaprinast, and chloroquinine in various cell types [67–70].  
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''IDH1'' mutation disables the decarboxylation reaction that converts αKG to isocitrate, a reaction important in hypoxic conditions where pyruvate influx from the TCA cycle is compromised and cells must use citrate and acetyl-CoA generated from glutamine and glutamate in order to maintain the ability to synthesise lipids [71]. In primary glioblastoma, where ''IDH1'' is overexpressed, knockdown of ''IDH1'' sensitises glioma-initiating cells with EGFR amplifications to erlotinib through decreased fatty acid and cholesterol synthesis [72].
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''IDH1'' mutation disables the decarboxylation reaction that converts αKG to isocitrate, a reaction important in hypoxic conditions where pyruvate influx from the TCA cycle is compromised and cells must use citrate and acetyl-CoA generated from glutamine and glutamate in order to maintain the ability to synthesize lipids [71]. In primary glioblastoma, where ''IDH1'' is overexpressed, knockdown of ''IDH1'' sensitizes glioma-initiating cells with ''EGFR'' amplifications to erlotinib through decreased fatty acid and cholesterol synthesis [72].
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2HG inhibits cytochrome c oxidase (complex IV of the ETC), preventing cytochrome c release into the mitochondrial matrix. This makes IDH mutated cells vulnerable to apoptosis through BAX/BAK mediated permeabilisation of the outer mitochondrial membrane, although normally this is prevented by BCL-2 binding to the BAX/BAK proapoptotic proteins [43,44]. Disrupting BCL-2 binding with venetoclax, a BH3 mimetic, results in apoptosis of IDH mutated cells but unmutated cells are relatively insensitive [73]. This has been observed in AML patients and glioblastoma models, though in the latter case BCL-xL appeared to be the primary target of the BH3 mimetic rather than BCL-2 [44].
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2HG inhibits cytochrome c oxidase (complex IV of the ETC), preventing cytochrome c release into the mitochondrial matrix. This makes ''IDH'' mutated cells vulnerable to apoptosis through BAX/BAK mediated permeabilisation of the outer mitochondrial membrane, although normally this is prevented by BCL-2 binding to the BAX/BAK proapoptotic proteins [43,44]. Disrupting BCL-2 binding with venetoclax, a BH3 mimetic, results in apoptosis of ''IDH'' mutated cells but unmutated cells are relatively insensitive [73]. This has been observed in AML patients and glioblastoma models, though in the latter case BCL-xL appeared to be the primary target of the BH3 mimetic rather than BCL-2 [44].
    
2HG downregulates nicotinate phosphoribosyltransferase (NAPRT1), which is an enzyme in the NAD+ salvage pathway. This leads to sensitivity to depletion of NAD+ in ''IDH1''-mutated cells by inhibition of nicotinamide phosphoribosyltransferase (NAMPT), another member of the pathway, with the preclinical compounds FK866 and GMX1778 leading to AMP kinase-initiated autophagy and cell death [45].
 
2HG downregulates nicotinate phosphoribosyltransferase (NAPRT1), which is an enzyme in the NAD+ salvage pathway. This leads to sensitivity to depletion of NAD+ in ''IDH1''-mutated cells by inhibition of nicotinamide phosphoribosyltransferase (NAMPT), another member of the pathway, with the preclinical compounds FK866 and GMX1778 leading to AMP kinase-initiated autophagy and cell death [45].
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In AML, the ''IDH1'' Arg132His (NM_005896.2/NP_005887.2) mutant gene expression signature is indicative of a cellular phenotype that is responsive to treatment with small molecules targeting ROS and NAP+/NADPH signalling and metabolism [75].  
 
In AML, the ''IDH1'' Arg132His (NM_005896.2/NP_005887.2) mutant gene expression signature is indicative of a cellular phenotype that is responsive to treatment with small molecules targeting ROS and NAP+/NADPH signalling and metabolism [75].  
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In pancreatic cancer cells, IDH1 has been linked to antioxidant defence as an adaptive strategy to cope with stress. Expression of ''IDH1'' is induced by HuR (Hu-Antigen R) after nutrient withdrawal or gemcitabine treatment. It has been suggested that this regulation is critical for pancreatic cancer cell survival under stress [76]. IDH1 mutations are rare in pancreatic cancer, however, probably owing to the importance of wild-type IDH1 function to pancreatic cancer cell survival.
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In pancreatic cancer cells, ''IDH1'' has been linked to antioxidant defense as an adaptive strategy to cope with stress. Expression of ''IDH1'' is induced by HuR (Hu-Antigen R) after nutrient withdrawal or gemcitabine treatment. It has been suggested that this regulation is critical for pancreatic cancer cell survival under stress [76]. ''IDH1'' mutations are rare in pancreatic cancer, however, probably owing to the importance of wild-type IDH1 function to pancreatic cancer cell survival.
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Mutant ''IDH1'' or ''IDH1'' knockdown radiosensitises cancerous and noncancerous cells[54,77], while ''IDH1'' overexpression is chemoprotective[78]. The radiosensitive phenotype of ''IDH1'' mutants is caused by both antioxidant depletion and impaired DNA damage response [54], the latter of which is associated with 2HG accumulation. The inhibition of ALKBH by 2HG also results in sensitisation of ''IDH1''-mutant cells to alkylating agents such as busulfan and CCNU [79], which provides an explanation for the sensitivity of ''IDH1''-mutated glioma to treatment with radiotherapy in the presence or absence of procarbazine, CCNU, and vincristine (the first two of which are alkylating agents) [80]. ''IDH1'' mutations also predict the response of glioblastoma to treatment with the DNA-alkylating agent temozolomide [81].
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Mutant ''IDH1'' or ''IDH1'' knockdown radiosensitizes cancerous and noncancerous cells [54,77], while ''IDH1'' overexpression is chemoprotective [78]. The radiosensitive phenotype of ''IDH1'' mutants is caused by both antioxidant depletion and impaired DNA damage response [54], the latter of which is associated with 2HG accumulation. The inhibition of ALKBH by 2HG also results in sensitization of ''IDH1''-mutant cells to alkylating agents such as busulfan and CCNU [79], which provides an explanation for the sensitivity of ''IDH1''-mutated glioma to treatment with radiotherapy in the presence or absence of procarbazine, CCNU, and vincristine (the first two of which are alkylating agents) [80]. ''IDH1'' mutations also predict the response of glioblastoma to treatment with the DNA-alkylating agent temozolomide [81].
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''IDH1''-mutated cancers are sensitive to PARP inhibitors, a phenotype that has been observed in AML and glioma [82,83], although the mechanism is unknown. Inhibition of the PARP-associated DNA repair pathway synergises with temozolomide in mutant glioma cells, and with daunorubicin in mutant AML, which suggests a treatment strategy that exploits the impaired DNA-repair pathway in ''IDH1''-mutants rather than using IDH1-mutant inhibitors may be beneficial [82]. In human cell models, a combination of ''IDH1'' mutation and ''ATM'' suppression caused sensitivity to irradiation and daunorubicin [82].
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''IDH1''-mutated cancers are sensitive to PARP inhibitors, a phenotype that has been observed in AML and glioma [82,83], although the mechanism is unknown. Inhibition of the PARP-associated DNA repair pathway synergizes with temozolomide in mutant glioma cells, and with daunorubicin in mutant AML, which suggests a treatment strategy that exploits the impaired DNA-repair pathway in ''IDH1''-mutants rather than using ''IDH1''-mutant inhibitors may be beneficial [82]. In human cell models, a combination of ''IDH1'' mutation and ''ATM'' suppression caused sensitivity to irradiation and daunorubicin [82].
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The fact that ''IDH1'' mutations arise very early in many cancers makes it an attractive therapeutic target, as the resulting tumour homogeneity decreases the risk of therapy resistance arising. IDH1-mutant inhibitors have been developed and show therapeutic promise in glioma, AML, and chondrosarcoma [84–87], although in AML these inhibitors may induce differentiation syndrome in some patients [88].
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The fact that ''IDH1'' mutations arise very early in many cancers makes it an attractive therapeutic target, as the resulting tumor homogeneity decreases the risk of therapy resistance arising. ''IDH1''-mutant inhibitors have been developed and show therapeutic promise in glioma, AML, and chondrosarcoma [84–87], although in AML these inhibitors may induce differentiation syndrome in some patients [88].
    
==Common Alteration Types==
 
==Common Alteration Types==